INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

In visually guided goal-directed movements, the CNS should first map the location of movement targets in a retinocentric visual-reference frame and then transform the visual-reference frame into an intrinsic motor-reference frame directly or indirectly through several intermediate representations in the head- or body-part-centered coordinates (Alexander and Crutcher 1990; Andersen et al. 1993; Atkeson 1989; Kawato et al. 1988). Such sensorimotor integration is known as transformation of coordinates and has been the subject of continuous interest for researchers in the field.

Although the transformation in the visually guided movements can potentially occur in a number of sites in the brain, recent neurophysiological and anatomical studies have provided much evidence that the ventral premotor cortex (PMv) is one of the best candidates. First, the PMv receives abundant corticocortical projections from the parietal cortex (Cavada and Goldman-Rakic 1989; Godschalk et al. 1984; Kurata 1991), which contains cells with a visual receptive field (Colby et al. 1993). The PMv is also heavily interconnected with the primary motor cortex (MI) (Leichnetz 1986; Muakkassa and Strick 1979) and projects to the spinal cord (Dum and Strick 1991; He et al. 1993). There is a sensory aspect of the transformation in the PMv: PMv neurons respond to visual and somatosensory stimuli conveying spatial information in retinocentric, head-centered, or body-part-centered coordinates (Boussaoud et al. 1993; Fogassi et al. 1996; Godschalk et al. 1985; Graziano et al. 1994, 1997b; Rizzolatti et al. 1981). On the other hand, the activity of neurons in the PMv also changes before forelimb movements (Caminiti et al. 1991; Godschalk et al. 1985; Kurata 1989, 1993; Kurata and Hoffman 1994; Kurata and Tanji 1986; Murata et al. 1997; Weinrich et al. 1984). Many of these movement-related neurons are selectively active when visual stimuli trigger a movement (Kurata and Wise 1988; Murata et al. 1997; Mushiake et al. 1991; Okano and Tanji 1987; Rizzolatti et al. 1987; Romo and Schultz 1987). Recently, motor aspects of the transformation in the PMv have been reported: the PMv contains neurons encoding the direction of reaching movement in retinocentric coordinates (Mushiake et al. 1997) and those encoding the direction of wrist movements in extrinsic space independent of forearm posture (Kakei et al. 2001). Furthermore, removal or inactivation of the PMv results in visuomotor deficits (Kurata and Hoshi 1999; Schieber 2000) or visual neglects (Rizzolatti et al. 1983).

However, little is yet known whether movement-related activity in the PMv reflects a head-centered visual-reference frame as an intermediate representation in a series of the transformations. To directly assess this possibility, we dissociated visual and motor-reference frames by applying shift prisms to the monkeys that were allowed to move their eyes freely during a reaching task. This protocol enabled us to examine which reference frame, visual, motor, or intermediate, was represented by neuronal activity in the PMv. Thus we focused on movement-related neurons whose activity changed during the reaction time (RT) period when visuomotor transformation for goal-directed reaching was expected to occur and compared their activity with that during a movement time (MT) period when the reaching was being executed. We also recorded movement-related activity in the MI to determine whether the PMv and MI have differential roles in the transformation.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Subjects and apparatus

Three male Japanese monkeys (Macaca fuscata) weighing 5.1-6.2 kg were trained to perform a visually guided task that involved reaching toward a target with the right arm. All the experiments were conducted in accordance with the standards of the Guide for the Humane Care and Use of Animals published by the American Physiological Society (http://www.the-aps.org/pub affairs/humane/pa_aps_guiding.htm). The apparatus and two of the three monkeys (monkeys 1 and 2) were the same as used in our previous report (Kurata and Hoshi 1999). The monkeys sat comfortably in a primate chair facing a 14-in CRT screen covered with a transparent touch panel that monitored the position of the monkey's hand on the screen by detecting local pressure. The positions on the touch screen were sampled at 500 Hz through an 8-channel, 12-bit A/D converter and stored in a laboratory computer. The screen was placed 30 cm away from the monkey's eyes, and the vertical centers of the screen and the monkey's head and body were aligned. An apparatus with two pairs of 4 × 4-cm wedge prisms (10° to the left or right) was placed immediately in front of the monkey's eyes. The apparatus was 46 cm wide, 17 cm high, and 8 cm deep and had a 4 × 8-cm hole in which a pair of the prisms was placed. Within the apparatus, each pair of the prisms was aligned horizontally on a mounting frame, and the prisms were separated by 5 cm, which matched the monkey's interocular distance. The mounting frame also had a pair of 4 × 4-cm holes without prisms. The monkey's visual field through the prisms apparatus matched the size of the CRT screen. Due to the size and placement of the prism apparatus, the monkey was not able to see its hand until the hand entered the visual field seen through the hole of the prism apparatus. A switch made of a 5 × 10-cm acrylic plate was placed at the end of the right armrest to serve as a hold key. The monkey's left arm was immobilized on the arm rest by Velcro straps.

Behavioral task

In each trial, the monkeys were required to reach for a 5 × 8-mm blue rectangular target that randomly appeared in one of nine locations (Fig. 1, A-C), with or without the prisms. The targets were separated by 6.0 cm or 10° of visual angle horizontally and vertically. Throughout the sessions, the location of the targets remained the same in terms of the visual coordinates, regardless of whether the 10° wedge prisms were present (Figure 1A-D) (see also Fig. 2 in Kurata and Hoshi 1999). The central target was always located at the intersection of the vertical and horizontal meridians of the visual coordinates (V08 in Fig. 1D), regardless of the prism conditions. When no prism was applied (Fig. 1B), the visual and motor coordinates of the targets matched. When the left 10° wedge prisms were applied, the motor coordinates were shifted 10° to the right of the visual coordinates (Fig. 1A). Conversely, when the right 10° wedge prisms were applied, the motor coordinates were shifted 10° to the left of the visual coordinates (Fig. 1C). The conditions in Fig. 1, A-C, were called the left prism, no prism, and right prism conditions, respectively (Kurata and Hoshi 1999). There were 15 motor targets (M01-15) in the motor coordinates (Fig. 1E). The target V08 corresponded to M07, M08, M09 in the right, no, and left prism conditions, respectively.

View larger version (54K): [in this window] [in a new window]   Fig. 1. The location of the 9 targets () on the CRT screen (the large rectangles) in the left (A), no (B), and right (C) prism conditions. Note that the target locations are the same in the visual coordinates, regardless of the prism condition (D). The large rectangles in A-C, E indicate the edge of the screen and touch panel. The central target in the visual coordinates (V08) was aligned at the intersection of the vertical and horizontal meridians. There were 15 motor targets (M01-15) in the motor coordinates (E, see text).

To start each trial, the monkey was required to press the hold key with its right hand. When it pressed the key continuously for a period varying between 1.5 and 3.0 s, a target was selected randomly from the nine possible locations and presented on the screen (Fig. 1). If the monkey released the hold key (movement onset) within 500 ms of the target's appearance, reached the touch screen within 500 ms of the movement onset, and hit the correct target, then 0.1 ml of orange juice was delivered as a reward. The RT was defined as the period between the appearance of the target and movement onset. The MT was defined as the period between movement onset and contact with the screen. We required the monkeys to initiate and execute the movement quickly so that they transformed the coordinates during the RT period with minimal sensory feedback during the MT period (Kurata and Hoshi 1999). For at least 2 wk before data collection, the monkeys were trained to perform the task with and without the prisms. In any prism condition, they were allowed to hit the screen first (not necessarily the target) and then make a corrective movement of their hand to the target. The corrective movements were highly variable from trial to trial. In some trials, the monkeys hit the targets without any corrective movements, whereas, in other trials, they continued to make the movements until they got rewards. We analyzed neuronal and EMG data only during the period up to the first contact with the screen. The monkeys adapted to the prisms, and after adaptation, the first contact point on the screen was generally close to the target, irrespective of the prism condition (see Fig. 3 of Kurata and Hoshi 1999). Eye movements were not monitored in monkeys 1 and 2 but were monitored in monkey 3 using an infrared oculometer system (R21CA, RMS, Hirosaki, Japan). All the monkeys were free to move their eyes at any time during a trial.

EMG recording

Electromyographic (EMG) activity was monitored bilaterally with surface and wire electrodes from the following muscles: the biceps and triceps brachii, anterior and lateral deltoid, extensor carpi radialis, flexor carpi ulnaris, trapezius, supraspinatus, infraspinatus, pectoralis major, rhomboid, thoracic and lumbar paravertebral muscles, gluteus maximus, quadriceps, and tibialis anterior. EMG activity from each muscle was stably recorded twice, before chamber implantation and near the completion of data collection from each monkey. The EMG data recorded at the two stages were separately analyzed (see following text). The EMG data were sampled at 100 Hz through the A/D converter and stored with the position data in the laboratory computer.

Neuronal recording method

After completion of the behavioral training, a stainless steel recording chamber (27 × 27 mm) and head-fixation bolts were implanted on the skull under aseptic conditions. The monkeys were anesthetized with pentobarbital sodium (30 mg/kg im) after induction with ketamine hydrochloride (8 mg/kg im) and atropine sulfate. During surgery, additional ketamine hydrochloride was given as necessary. Antibiotics and analgesics were used to prevent postsurgical infection and pain.

After complete recovery from the surgery (more than 7 days), neuronal activity was recorded from the PMv and MI during task performance. The explored areas were selected based on the central and arcuate sulci and the arcuate spur that were observed during surgery. It was confirmed by histological reconstruction that the areas covered the proximal forelimb representations of the PMv and MI (Gentilucci et al. 1988; Kurata and Tanji 1986). We used glass-insulated Elgiloy microelectrodes (1.5-2.0 M at 333 Hz) for single-unit recording. The microelectrodes were inserted through the dura mater with a hydraulic microdrive (Narishige, MO95). The same microelectrodes were used for intracortical microstimulation (ICMS). Each ICMS consisted of a train of 11 cathodal pulses of less than 50 µA and 0.2-ms duration at 333 Hz. ICMS was used to identify the MI physiologically, and neuronal activity within the MI was recorded in the proximal forelimb representation areas but not in the distal forelimb or orofacial areas. We isolated neurons with an increased discharge rate during the RT period and then examined their response to visual stimuli. Two types of visual stimuli were used: the same stimuli that served as targets were presented for 100 ms and an experimenter's hand moving toward the monkey's eyes (Fogassi et al. 1992, 1996). When a neuron showed increased activity during the RT period and did not respond to these visual stimuli, its activity was recorded in the three prism conditions. Blocks of trials were recorded in the no prism condition first, then in either the right or left prism condition, followed by the no prism condition a second time, and finally in the remaining prism condition. The order of the right and left prism conditions was randomized in a daily session. The second no prism condition was used to check the excitability of the cell. In each block, neuronal activity was recorded for approximately 200 trials, i.e., more than 20 trials for each of the nine targets. If stable neuronal activity was recorded, an optional recording was done in the no prism condition using two sets of targets shifted to the locations in Fig. 1, A and C.

Data analysis

For each of the nine targets in the three prism conditions, a raster display of recorded neuronal activity was aligned with the movement onset, and a peri-event histogram with a 20-ms binwidth was created to show neuronal activity for each target in one of the prism conditions (Figs. 5, 7, and 9). For each display and quantitative analysis, the data after the first 10 trials during adaptation to the prisms (Kurata and Hoshi 1999) were taken because, in this study, it was essential to obtain the data best corresponding to the motor coordinates in each prism condition. Furthermore, the data were added to the database only when neuronal activity was stably recorded for more than 10 trials for each target in a prism condition and the neuron showed a consistent activity pattern throughout the recorded trials. The mean discharge rate and its SD during the 0.5- to 1.5-s interval before target presentation (premovement period) were calculated first. If the neuronal activity exceeded 2.56 SD (P < 0.01) during the RT in at least two consecutive bins of at least three of the nine histograms in the no prism condition, it was defined as movement-related activity. Then the time when the activity first exceeded the threshold value was defined as the onset of neuronal activity in each display. After the earliest onset of neuronal activity was obtained from the nine displays, the mean discharge rate during the period from the earliest onset of neuronal activity to movement onset was calculated in each trial, regardless of whether the neuron showed a statistically significant change during the period, in each of the nine displays. The mean discharge rate during the period in each trial was used for subsequent quantitative and statistical analyses. For each of the movement-related neurons, a mean discharge rate and SD during MT in each trial were also calculated for quantitative and statistical analysis.

To classify neuronal activity, the mean discharge rates during the sampling times (either RT or MT) were compared statistically using the general linear model (GLM) of SYSTAT for Windows (ver. 8.0.2, Chicago, IL). First, we selected neurons with activity dependent on target location in either the visual or motor coordinates. Without the variation, it cannot be judged whether the activity reflects visual or motor space. Second, it was essential to judge whether the activity reflected visual or motor space, and/or prism effects. Thus we compared neuronal activity during the RT or MT at the visual and motor target locations (Fig. 1, D and E) in the three prism conditions, using linear regression models

(1)

(2)

Where target_v in Eq. 1 and target_m in Eq. 2 represent target locations in visual and motor coordinates (Fig. 1, D and E), respectively, and prism represents the three prism conditions and are selected as factors for GLM. Throughout the analysis using Eqs. 1 and 2, we selected only neurons with statistically significant variation dependent on target location (either target_v or target_m, P < 0.01) to judge whether the activity reflects visual or motor space.

If factor analysis for prism was not statistically significant (P > 0.01) in Eq. 1, but was statistically significant (P < 0.01) in Eq. 2 and if that for target_v was statistically significant (P < 0.01) in Eq. 1, then the activity was judged as consistently dependent on target location in the visual coordinates only, regardless of whether the prisms were present or absent (termed V type). This means that when a target was located at the same position in visual coordinates, the neuronal activity was always constant regardless of the prisms, and, dependent on the prisms, the activity was variable even when a target was constantly located at a given position in the motor coordinates. Similarly, if factor analysis for prism was not statistically significant (P > 0.01) in Eq. 2 but was statistically significant (P < 0.01) in Eq. 1 and if that for target_m was statistically significant (P < 0.01) in Eq. 2, then the activity was judged as consistently dependent on target location in the motor coordinates (termed M type). This indicates that when a target was located at the same position in the motor coordinates, the neuronal activity was always constant regardless of the prisms, and, dependent on the prisms, the activity was variable even when a target was constantly located at a given position in the visual coordinates. If factor analysis for prism was statistically significant (P < 0.01) in both Eqs. 1 and 2, then the activity was judged as differently active in both of the visual and motor coordinates (termed B type). In other words, dependent on the prisms, the neuronal activity was variable even when a target was located at the same position in the visual or motor coordinates. Finally, if factor analysis for prism was not statistically significant (P > 0.01) in Eqs. 1 nor 2, then the activity was judged as indifferently active in the two coordinates (termed N type). That is, N-type activity showed no prism effect, even when the neurons changed their activity depending on target locations in the visual or motor coordinates. The discharge rates of the movement-related neurons during MT and quantified EMG data were similarly analyzed and were classified into the four types (V, M, B, and N). Equations 1 and 2 were also used to examine whether differences in reaction and movement times and accuracy of reaching between visual and motor targets and prism conditions were statistically significant. In these analyses, we set 0.01 as the significance level, because each unit activity was dually compared with both Eqs. 1 and 2, so that type-1 error could be lower than 0.05 usually adopted for GLM. When an optional recording was obtained in the no prism condition at the target locations in Fig. 1, A and C, the data were included in the statistical analysis. As a result, the two equations were more balanced, and enabled us to check the validity of Eq. 2 without the data collected in the prism conditions.

After the neuronal activities were classified into the four types, the correlation coefficients of each neuron to the visual and motor coordinates were computed to obtain to what extent the neuron modulated its activity dependent on the coordinates, using the average firing rates during RT and MT. The formula used was

(3)

This statistic, first introduced by Pearson (1900), is called the Pearson product moment correlation coefficient and has been used for a similar purpose to that used in this study (Batista et al. 1999). To compute the correlation in visual space coordinates (r_visual), x_i is the average firing rate for a reach to a given visual target i under the no prism condition, and y_i is a reach to the same target under either the left or right prism conditions, is the average of the x_i; is the average of y_i; and n is the number of targets (9) that overlapped in the two prism conditions. To compute the correlation in motor space coordinates (r_motor), x_i is the average firing rate for a reach to a given motor target i under the no prism condition, and y_i is a reach to the same motor target under either the left or right prism condition, is the average of the x_i; is the average of y_i; and n is the number of motor targets (6) that overlapped in the two prism conditions (Fig. 1). If the coefficient, r_visual, is 1, then it indicates the neuronal activity perfectly reflects visual space. In this case, r_motor of the neuron should be close to 0. On the other hand, if r_motor is 1, then it can be judged that motor space is reflected in the activity.

Histology

After collecting single-unit data, muscimol was injected into the PMv of monkeys 1 and 2 (Kurata and Hoshi 1999). When all the experiments were completed, electrolytic marking lesions were produced by passing 20 µA of cathodal DC through the microelectrodes for 15 s. Nine to 10 days later, the monkeys were deeply anesthetized with pentobarbital (50 mg/kg im) and were perfused through the heart with saline followed by a fixative containing 3.7% formaldehyde in 0.1 M phosphate buffer at pH 7.4, followed by 10 and 20% sucrose solutions in 0.1 M phosphate buffer at pH 7.4.

After marking the location of the recording chamber with five pins at known electrode coordinates, the brain was removed from the skull and photographed. Later it was sectioned serially at 50-µm thickness in the frontal plane using a freezing microtome. The PMv was defined as the area within the dysgranular frontal cortex rostral to the primary motor cortex (MI) and lateral to the arcuate spur, where ICMS at an intensity less than 50 µA does not evoke muscle activity (Barbas and Pandya 1987; Kurata 1993, 1994; Kurata and Hoffman 1994; Kurata and Hoshi 1999; Matelli et al. 1985).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

RT and MT

The mean RTs and MTs times for movements toward the nine targets in the three different prism conditions by the three monkeys are shown in Fig. 2 and listed in Table 1. In all the monkeys, the mean RTs were shorter than 300 ms, regardless of target location or prism condition, and there were no statistically significant differences in RT between any visual or motor target locations, or between any prism conditions (GLM, P > 0.01). MT to a given target did not vary with prism condition. Difference between prism conditions (prism in Eq. 2) was statistically not significant (GLM, P > 0.01). On the other hand, MT depended on the motor target location. Difference between the motor target locations (target_m in Eq. 2) was statistically significant (GLM, P < 0.01). Because the distances from the hold key (starting point) to the former visual targets were longer than the distances to the latter targets, these observations suggest that the MT depended on the movement distance, and not on presence of the prisms.

View larger version (28K): [in this window] [in a new window]   Fig. 2. Means and SE (in ms) of the reaction (RT) and movement (MT) times of the 3 monkeys (1-3) in the 3 prism conditions (left, no, and right prisms). The numbers (e.g., V02 and M01) on the abscissas correspond to the visual and motor target locations, respectively, in each prism condition (Fig. 1).

Reaching movement accuracy

Table 2 shows the average movement accuracy in the three prism conditions. To measure movement accuracy, the first 10 trials after changing the prisms, during which adaptation was taking place, were excluded (see Fig. 3 in Kurata and Hoshi 1999). Differences in the movement accuracy of monkey 1 under the three prism conditions were not statistically significant (GLM, P > 0.01), whereas monkeys 2 and 3 showed statistically significant difference in movement accuracy between the prism conditions (GLM, P < 0.01). In the three monkeys, means of the first contact points were located to the left of the target. This is partly due to mechanical properties of the touch screen. Because the monkeys tended to contact the screen with their index, middle, and ring fingers, the contact point was detected as a weighted average of the multiple contact points, which were usually left of the target. Compared with the inter-target distance (60 mm), the average distance between the center of each target and the first contact point was relatively small, regardless of the presence or absence of the shift prisms.

EMG activity during task performance

Of the muscles recorded, the anterior deltoid was found to be a prime mover for the reaching movements in all three monkeys. The muscle was active immediately before and during reaching movements. Figures 3 and 4 show representative EMG activity from the right anterior deltoid of monkey 1 and its quantified data during RT (between EMG onset and movement onset) and MT, respectively. In the motor coordinates, differences in the EMG activity during both RT and MT between prism conditions (prism in Eq. 2) were not statistically significant (GLM, P > 0.01), while difference between the motor targets (target_m in Eq. 2) was statistically significant (GLM, P < 0.01; Fig. 4, right). In the visual coordinates, however, differences in the EMG activity during RT and MT between prism conditions (prism in Eq. 1) were statistically significant (GLM, P < 0.01; Fig. 4, left). The EMG activities during both RT and MT were classified as M type. Thus the right anterior deltoid muscle changed its activity in relation to the targets which the movements were directed in the motor, but not visual, coordinates.

View larger version (33K): [in this window] [in a new window]   Fig. 3. Electromyographic (EMG) activity of the right anterior deltoid muscle, which was found to be a prime mover of the reaching movements, in the left (A), no (B), and right (C) prism conditions. EMG histograms were aligned at the movement onset (Mvt). The activity during RT was classified as M type (see METHODS). In each panel, the locations of the visual and motor targets (such as V02 and M03) are indicated (Fig. 1).

View larger version (34K): [in this window] [in a new window]   Fig. 4. Quantitative analysis of the EMG shown in Fig. 3 during RT and MT for the visual and motor targets in the 3 prism conditions. An arbitrary A/D conversion unit is used as the ordinate. The other formats are the same as in Fig. 2.

The other right shoulder and upper arm muscles, such as supra- and infraspinatus, rhomboid, trapezius, and teres major, were active during the task, but the activity was similar for each of the nine targets. The right proximal and distal forelimb muscles, such as the biceps and triceps brachii, extensor carpi radialis, flexor carpi ulnaris, changed activity after onset of reaching movements. None of the left shoulder or forelimb muscles changed activity during reaching movements. No muscle was specifically active during the holding period before a target was presented. Table 3 summarizes activity patterns of the recorded muscles in the three monkeys, classified as M, N, and B types. No V-type activity was found in any muscle.

Movement-related activity reflecting visual space

We found V-type activity almost exclusively during the RT period, and the activity was almost exclusively recorded in the PMv (Table 4). Figure 5 shows an example of V-type activity recorded in the PMv. The neuron changed its activity during RT, and no significant change of activity was observed during MT. The neuron showed activity dependent on target location during RT. Most remarkably, activities toward the same visual targets were almost identical in the three prism conditions. In contrast, the activities toward the same motor targets differed in the prism conditions. Figure 6 shows a quantitative analysis of the data shown in Fig. 5 in the visual and motor coordinates. Difference in the activity during RT between the visual targets (target_v in Eq. 1) was statistically significant (GLM, P < 0.01). When activities in the visual coordinates were compared, difference between prism conditions (prism in Eq. 1) was not statistically significant (GLM, P > 0.01). In contrast, when activities in the motor coordinates were compared, prism in Eq. 2 was statistically significant (GLM, P < 0.01). Thus the PMv activity during RT was classified as V type.

View larger version (25K): [in this window] [in a new window]   Fig. 5. A typical neuron with V-type activity (activity consistently dependent on target location in the visual coordinates only)during RT recorded in the PMv. Numbers (e.g., V02) in the panel indicate the locations of visual targets (Fig. 1). The rasters and histograms were aligned with movement onsets (Mvt). The tics before the movement onset in each raster indicates when the target was presented (TS). The tics after movement onset indicate the first contact with the screen (Con), acquisition of the target (Acq), and reward delivery (Rew). Note that this neuron did not show significant activity change during MT, compared with the premovement time (see METHODS). Its average lead-time to movement onset was 262 ms.

View larger version (25K): [in this window] [in a new window]   Fig. 6. Quantitative analysis of the PMv neuron shown in Fig. 5. The ordinates indicate mean discharge frequencies during RT. The other formats are the same as in Fig. 4. The correlation coefficients, rvisual and motor, in Eq. 3 in METHODS were 0.95 and 0.82, respectively. Because the neurons shown in Fig. 5 did not show significant activity change during MT, no quantitative analysis during MT was done.

Movement-related activity reflecting motor space

We found M-type activity predominantly during the RT period, and the activity constituted 19 and 37% of the classified activities (V, M, B, or N) during RT in the PMv and MI, respectively (Table 4). Figure 7 shows a representative M-type activity during RT recorded in the PMv. Activities toward the same motor targets were almost identical in the three prism conditions. In contrast, the activities toward the same visual targets differed in the prism conditions. Figure 8 shows quantified data of the neuron in Fig. 7 that were aligned in the visual and motor coordinates. When activities during RT were compared in the motor coordinates, the difference between prism conditions (prism in Eq. 2) was not statistically significant (GLM, P > 0.01). In contrast, when the data were compared in the visual coordinates, difference between prism conditions (prism in Eq. 1) was statistically significant (GLM, P < 0.01). During MT, activity of the same neuron was classified as B type.

View larger version (32K): [in this window] [in a new window]   Fig. 7. Representative movement-related activity of a PMv neuron classified as M type (activity consistently dependent on target location in the motor coordinates) during RT (see METHODS). Activity during MT of the same neuron was classified as B type (activity judged differently active in visual and motor coordinates). The discharge rate of the neuron during RT depended mainly on the horizontal motor coordinates. The mean lead-time to movement onset of this neuron was 227 ms. The formats are the same as in Fig. 5.

View larger version (34K): [in this window] [in a new window]   Fig. 8. Quantitative analysis of the PMv neuron shown in Fig. 7 during RT and MT. The other formats are the same as in Fig. 6. The correlation coefficients (rvisual and rmotor) in Eq. 3 were 0.75 and 0.91 during RT and were 0.58 and 0.76, respectively, during MT.

Movement-related activities classified as B and N types

B-type activities were found during RT and MT, and was found about equally in the PMv and MI (Table 4). Figure 9 shows a representative B-type activity during RT recorded in the PMv, and its activity during MT was also classified as B type. Figure 10 shows quantified data of the neuron in Fig. 9, which were aligned in the visual and motor coordinates. During RT and MT, activities toward the same motor and visual targets differed in the three prism conditions. When activities during RT and MT were compared in the visual and motor coordinates, differences between prism conditions (prism in Eqs. 1 and 2) were statistically significant (GLM, P < 0.01). Thus the activities were classified as B type. We also found activities classified as N type during RT and MT in the PMv and MI (data not shown).

View larger version (43K): [in this window] [in a new window]   Fig. 9. Representative PMv movement-related activity classified as B type during both RT and MT. The mean lead-time to movement onset of this neuron was 216 ms. The formats are the same as in Fig. 5.

View larger version (35K): [in this window] [in a new window]   Fig. 10. Quantitative analysis of the PMv neuron shown in Fig. 9 during RT and MT. The other formats are the same as in Fig. 6. The correlation coefficients (rvisual and rmotor) in Eq. 3 were 0.42 and 0.58 during RT and were 0.35 and 0.75, respectively, during MT.

Number of neurons with each classified type during RT and MT

Tables 4 and 5 summarize the number of neurons with classified types in the PMv and MI of the three monkeys. During RT, the most remarkable distinction between the PMv and MI was the proportion of neurons with V-type activity. The neurons with V-type activity constituted 21% in the PMv but only 1% in the MI (1 neuron). In contrast, M-type neurons were more numerous in MI the (37%) than in the PMv (19%). Proportions of B and N-type neurons were similar in the two areas (35 vs. 36% for B type and 26 vs. 26% for N type).

Of the 117 PMv neurons and 76 MI neurons whose activity were classified as the four types during RT, 107 (91.4%) and 69 (90.8%) neurons, respectively, were also active during MT. However, the proportion of the classification types changed greatly from RT to MT. During MT, none of the PMv neurons with V-type activity during RT were classified as V type but changed to the other types. Some neurons with M-type activity during RT was also classified as M type during MT. Others with M-type activity changed to either B (Figs. 7 and 8) or N types, but not to V type, during MT. Table 5 indicates that there was no systematic change from one type of activity during RT to the other type during MT. As a whole, neurons with B-type activity were most numerous both in the PMv (56%) and MI (66%) during MT. No activity type was consistently related to eye movements throughout RT and MT.

For 42 of the statistically analyzed 285 neurons (24 of 119 PMv neurons and 18 of 76 the MI neurons), an optional recording was obtained in the no prism condition at the target locations in Fig. 1, A and C (see METHODS). When the data with optional recording were compared with those without the recording, a majority of the neurons during RT [22 of 24 PMv neurons (91.7%) and 15 of 18 MI neurons (83.3%)] and MT [19 of 21 PMv neurons (90.5%) and 13 of 17 MI neurons (76.5%)] were classified as the same type.

Correlation of the classified activities in the PMv and MI to the visual and motor coordinates

Tables 6 and 7 indicate how closely each type of activity in the PMv and MI was correlated to the visual or motor coordinates, by showing means ± SE of the correlation coefficients (r_visual vs. r_motor calculated from Eq. 3). During RT (Table 6), V-type activities frequently had r_visual values close to 1.0. In the PMv, mean r_visual values of the V-type activities were 0.710-0.865, whereas their mean r_motor values were much less (0.352-0.577). By contrast, M-type activities frequently had r_motor values close to 1.0. Mean values of their r_motor were 0.858-0.767 in the MI and 0.915-0.828 in the PMv, and the values were higher than those of their r_visual (0.552-0.614 in the MI and 0.303-0.780 in the PMv). Common to the PMv and MI, B-type activities frequently had relatively high r_visual and r_motor values (most frequently > 0.5), whereas N neurons had lower r_visual and r_motor values (most frequently < 0.5). Difference in the correlation coefficient (r_visual or r_motor) among the four types of activities was statistically significant particularly in the PMv. These trends were similar during MT (Table 7), although very few V-type activities were recorded even in the PMv.

Lead times of the movement-related activity before movement onset

We analyzed the lead-time from the onset of the V-, M-, B-, and N-type activities to movement onset. Table 8 shows the mean lead-times of each classified types during RT in the PMv and MI of the three monkeys. In monkeys 1 and 2, the lead-times of the movement-related activities in the PMv were significantly shorter than those in the MI (GLM, P < 0.05). In both the PMv and MI, however, difference in the lead-time between the V, M, B, and N types was not statistically significant (GLM, P > 0.05).

Location of neurons

Figure 11 shows the distribution of movement-related neurons, classified by activity during RT, in the PMv and MI of monkey 2. In the MI, the neurons were located mainly in the proximal forelimb and trunk representation areas. In the PMv, on the other hand, the majority of these neurons were located in the caudal part of the PMv, close to the border between the PMv and MI. As shown in Fig. 11, the V-, M-, B, and N-type neurons were similarly distributed in the PMv and MI, and from surface views we could not discern any tendency toward clustering.

View larger version (22K): [in this window] [in a new window]   Fig. 11. Location of the V-, M-, B-, and N-type neurons in the PMv and MI of monkey 2. The neuronal activities were classified according to their activity during RT (see METHODS). Full circles, the location of neurons. The size of the circle shows the number of cells recorded in the track. Short horizontal bars indicate that no neuron classified as V, M, B, or N was recorded in the tracks. The interrupted oblique line in the panel indicates the cytoarchitectonic boundary between areas 4 and 6. Arc, arcuate sulcus; Cent, central sulcus; Prin, principal sulcus; SPS, superior precentral sulcus; Spur, arcuate spur.

Figure 12 shows a histological reconstruction of the location of the movement-related neurons in the PMv. Most were located on the dorsal surface of the PMv and within the ventral bank of the arcuate spur. Only a few neurons were recorded in the caudal bank of the arcuate sulcus in the three monkeys (data not shown). The V-, M-, B-, and N-type neurons were recorded at various depths in the same track. In some tracks, the M-type neurons were located deeper than the V-type neurons. In other tracks, however, they were intermingled, and no constant tendency for the location of V-, M-, B-, and N-type neurons was observed.

View larger version (21K): [in this window] [in a new window]   Fig. 12. Histological reconstruction of the V-, M-, B-, and N-type neurons in selected frontal sections (A-D) in Fig. 11. See keys for the locations of V-, M-, B-, and N-type neurons. The rostrocaudal levels of the sections are shown on the brain at the bottom right.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Classification of movement-related activity by statistical models

We found several types of movement-related activity in the PMv during RT and MT: activity closely related to head-centered visual space (V type), activity closely related to motor space (M type), and activity reflecting both visual and motor space (B type), and activity reflecting neither of them (N type). Of these four types of movement-related activity, the presence of neurons with V-type activity during RT clearly distinguished the PMv from the MI. The MI had virtually no V type in RT and MT periods. The anterior deltoid muscle, the prime mover of reaching, showed M-type activity during RT. Other muscles showed M, B, and N types during RT and MT, but we did not observe V-type activity in any muscle.

Classification by the statistical models (Eqs. 1 and 2) seems appropriate to distinguish the activity types. In the analysis, the motor coordinates of the targets were used to judge whether the activity was dependent on where the reaching movements were directed. Ideally, the first contact point on the screen should be used to examine this relationship; however, it is impossible to examine such data statistically because the first contact points were not exactly on the targets, but the monkeys tended to hit slightly to the left of the targets (Table 3). Thus it is highly possible that we underestimated the number of M-type activities and overestimated the number of B- and N-type activities. On the other hand, we could statistically verify whether the activities reflected visual space because the targets had the identical location in visual space regardless of the application of prisms.

When the data were obtained optionally at the motor target locations in Fig. 1, A and C, in the no prism condition, Eqs. 1 and 2 in METHODS were more balanced. When the movement-related activities with and without the optional data were compared using the two equations, a vast majority of them were classified as the same type (see RESULTS). Thus we confirmed the validity of Eq. 2, even when the optional data were not recorded. Furthermore, using Eq. 3 in METHODS, V and M types were found highly correlated to the visual and motor coordinates of target location, respectively (Tables 6 and 7). This suggests that V-type activity reflects visual space, whereas motor space is represented in M-type activity. Accordingly, we will first discuss our interpretation of the functional roles of these neurons in reaching motor behavior.

Movement-related activity closely linked to visual space

First, it should be stressed that the V-type activity in the PMv in this study was not passive response to visuospatial inputs (Boussaoud et al. 1993; Fogassi et al. 1996; Godschalk et al. 1985; Graziano et al. 1994; Rizzolatti et al. 1981; Weinrich and Wise 1982). Instead, they were active only when reaching movements were initiated after visual targets were presented. Thus we regarded the V-type activity as "movement-related" (Kurata and Hoffman 1994; Kurata and Tanji 1986). Similar observations in the PMv were recently reported (Mushiake et al. 1997), but those activities are considered different from the V type in this study. They required the monkeys to make visual fixation at one of two points throughout a trial (Mushiake et al. 1997). During the trial, a target peripheral to the fixation point was presented. In their study, they found that the movement-related activity of some PMv neurons was dependent on the retinocentric location of the targets. In our study, on the other hand, the monkeys were free to make eye movements during any phase of a trial. Accordingly, we found movement-related neurons in the PMv whose activity was dependent on the head-centered visual location of the targets, and not on their retinocentric location or the direction of reaching.

It is reported that the PMv contains neurons whose visual and somatosensory receptive fields remained in the same location even when the monkey was not fixating and the eyes were moving (Graziano and Gross 1998). Furthermore, a subset of the neurons continued to respond in the dark as if the object were still present and visible. Such cells exhibit "object permanence," encoding the presence of an object that is no longer visible. It has been suggested that those cells may underlie the ability to reach toward or avoid objects that are no longer directly visible (Graziano et al. 1997a). We propose that the V-type activity observed in this study reflects motor commands directly converted from either retinocentric or head-centered visuospatial information, represented by the neuronal responses to visual stimuli in the PMv (Boussaoud et al. 1993; Fogassi et al. 1996; Graziano et al. 1994; Rizzolatti et al. 1981) and intraparietal cortex (Colby et al. 1993, 1995) that project to the PMv (Kurata 1991; see also a review by Wise et al. 1997). This should be clarified in future experiments. Because few V-type activities were recorded in the MI, it is also suggested that direct spatial conversion from visual input to motor output occurs in the PMv but much less in the MI.

Because visual and motor space were dissociated in our experiment design, it can be interpreted that the V-type activity represents an extrinsic frame, related to the direction of movement in visual space, and that the M-type activity reflects an intrinsic frame, related to the direction of movement in motor space. Our results are comparable to the reports by Kakei et al. (1999, 2001) who dissociated different coordinate frames related to wrist movements: extrinsic (related to the direction of movement in space) and intrinsic (related to the activity of individual or groups of muscles and related to the angle of the wrist joint) frames. They found that nearly all of the movement-related neurons in the PMv were "extrinsic-like" (Kakei et al. 2001), whereas the MI contains both "muscle-like" and extrinsic-like activities (Kakei et al. 1999). Although the proportion of extrinsic and "intrinsic" activities in the PMv and MI seems different from our results, it can be explained by difference in experiment designs. It is more important to notice that the PMv contains neurons representing an extrinsic frame, thus contributing to transformation of coordinates.

Movement-related activity possibly representing final motor commands

In contrast to V type, M-type activities were frequently recorded in both the PMv and MI, and their activity changed in association with target location or the direction of reaching toward them but not with the visuospatial target location. These observations suggest that the activity of the M-type activity reflects final motor commands to lower motor centers such as the spinal cord, to which both the PMv and MI project directly (Dum and Strick 1991; He et al. 1993). We did not find any distinction between the M-type activity in the PMv and MI. However, it is possible that output from the neurons with M-type activity in the PMv may be sent to the MI (Leichnetz 1986; Muakkassa and Strick 1979), where it is further processed to make muscle activation patterns within the MI.

Movement-related activity other than V and M types

Besides the V and M types, we recorded a number of movement-related neurons in the PMv and MI that did not show a close relationship to visual or motor coordinates (B and N types). The presence of the neurons can be interpreted in four ways. First, they could convey information on motor space or final motor commands because similar activities were found in EMG of the upper arm and shoulder (Table 3), i.e., in activity during MT. Second, the neurons may represent an intermediate stage of processing that is necessary for coordinate transformation, and the PMv may modify the relationship between the V and M types by changing the activity of the B and N types. Third, they might represent noisy elements of neuronal activity and play no specific role in the transformation of coordinates or in generating the final motor commands necessary for directing the arm toward the target. Fourth, the neurons might contribute to other aspects of motor control rather than those required in our task. Because the design of our study did not enable us to identify which interpretation is most appropriate, other studies will be necessary to specify the functional role of the B- and N-type activities.